X-ray detector, mobile device and host device

ABSTRACT

A mobile device, a host device, and an X-ray detector are provided. The mobile device includes a first communicator configured to receive identification information of the X-ray detector from the X-ray detector, and a second communicator configured to send the received identification information of the X-ray detector to the host device.

CROSS-REFERENCE TO RELATED APPLICATION

This application claims priority from Korean Patent Application No.10-2015-0164292, filed on Nov. 23, 2015, and Korean Patent ApplicationNo. 10-2016-0130569, filed on Oct. 10, 2016, in the Korean IntellectualProperty Office, the disclosures of which are incorporated herein byreference in their entireties.

BACKGROUND 1. Field

Apparatuses and methods consistent with example embodiments relate to anX-ray detector paired with a host device, a mobile device used forpairing, a host device paired with an X-ray detector, an X-ray imagingapparatus including an X-ray detector, a host device, and a mobiledevice, and a method of pairing an X-ray detector with a host device.

2. Description of the Related Art

An X-ray detector is a device used to detect X-rays transmitted throughan object and to image an internal structure of the object. When anX-ray detector detects X-rays and converts the detected X-rays intoelectric signals, a host device of an X-ray imaging apparatus processesthe electric signals to generate an X-ray image indicating an anatomicalstructure of an object.

Recently, wireless X-ray detectors have been developed and used, and maybe removable and thus used for various purposes.

To this end, wireless X-ray detectors perform a paring task forconnecting an X-ray detector to be used with an X-ray imaging apparatusbefore X-ray imaging.

SUMMARY

Example embodiments may address at least the above problems and/ordisadvantages and other disadvantages not described above. Also, theexample embodiments are not required to overcome the disadvantagesdescribed above, and may not overcome any of the problems describedabove.

Example embodiments provide an X-ray detector, a mobile device, a hostdevice, an X-ray imaging apparatus including an X-ray detector, a mobiledevice, and a host device, and an X-ray detector pairing method, inwhich an X-ray detector is simply and accurately paired with a hostdevice through a mobile device, the mobile device is configured tosimply and accurately pair the host device and the X-ray detector, andthe host device is simply and accurately paired with the X-ray detectorthrough the mobile device.

According to an aspect of an example embodiment, there is provided amobile device including a first communicator configured to receiveidentification information of an X-ray detector from the X-ray detector,a second communicator, and a controller configured to control the secondcommunicator to send the received identification information of theX-ray detector to a host device.

The first communicator may be further configured to receive detectorinformation of the X-ray detector from the X-ray detector, the detectorinformation having any one or any combination of a remaining batterycapacity, a size, a resolution, a pixel size, calibration information,and a read-out rate of the X-ray detector.

The mobile device may further include a display configured to displayeither one or both of the detector information and a screen forreceiving an approval of a pairing with the host device, and an inputinterface configured to receive an input of the approval of the pairingwith the host device.

The first communicator may include any one or any combination of a NearField Communication (NFC) module and a Radio Frequency Identification(RFID) reader, and is further configured to receive the identificationinformation of the X-ray detector from the X-ray detector in response tothe controller tagging the X-ray detector, the second communicator mayinclude any one or any combination of a beacon and a Bluetooth LowEnergy (BLE) module, and the controller may be further configured tocontrol the second communicator to transmit a signal having the receivedidentification information of the X-ray detector to the host device inresponse to the first communicator receiving the identificationinformation of the X-ray detector.

The mobile device may further include a display configured to display ascreen for receiving an approval of a pairing with the host device,before the sending of the received identification information of theX-ray detector to the host device or after the host device receives apairing response from the X-ray detector.

According to an aspect of an example embodiment, there is provided ahost device including a first communicator configured to receiveidentification information of an X-ray detector from a mobile device, asecond communicator, and a controller configured to control the secondcommunicator to send a pairing request having the receivedidentification information to the X-ray detector.

The host device may further include a display configured to display ascreen for receiving an approval of a pairing with the X-ray detector ofwhich the identification information is received.

The host device may further include an input interface configured toreceive an input of the approval of the pairing with the X-ray detector.

The controller may be further configured to control the secondcommunicator to send a pairing approval request to the mobile device.

The second communicator may include any one or any combination of aWi-Fi module and a Wi-Fi Direct module, and the controller may befurther configured to control the second communicator to send thepairing request having the received identification information to theX-ray detector in response to the first communicator receiving theidentification information of the X-ray detector.

The second communicator may be further configured to, in response to thehost device being paired with the X-ray detector of which theidentification information is received, receive X-ray data and detectorinformation of the X-ray detector from the X-ray detector, the detectorinformation having any one or any combination of a remaining batterycapacity, a size, a resolution, a pixel size, a read-out rate, andcalibration information of the X-ray detector.

The controller may be further configured to control the secondcommunicator to release a pairing with the X-ray detector in response tothe first communicator receiving identification information of a newX-ray detector.

According to an aspect of an example embodiment, there is provided anX-ray detector including a detector configured to detect an X-ray, andconvert the detected X-ray into X-ray data, a first communicatorconfigured to send identification information of the X-ray detector to amobile device, a second communicator, and a controller configured tocontrol the second communicator to pair a host device with the X-raydetector in response to the second communicator receiving a pairingrequest from the host device.

The first communicator may include any one or any combination of a NearField Communication (NFC) tag and a Radio Frequency Identification(RFID) tag in which the identification information is recorded.

The second communicator may include any one or any combination of aWi-Fi module and a Wi-Fi Direct module, and the controller may befurther configured to control the second communicator to send a responseto the host device to pair the X-ray detector and the host device inresponse to the second communicator receiving the pairing request fromthe host device.

BRIEF DESCRIPTION OF THE DRAWINGS

The above and/or other aspects of the disclosure will become apparentand more readily appreciated from the following description of exampleembodiments, taken in conjunction with the accompanying drawings ofwhich:

FIGS. 1A and 1B are diagrams showing an exterior appearance of an X-rayimaging apparatus according to an example embodiment;

FIGS. 2A, 2B, and 2C are diagrams showing a process of pairing an X-raydetector with a workstation using a mobile device, according to anexample embodiment;

FIG. 3 is a control block diagram of an X-ray imaging apparatusaccording to an example embodiment;

FIG. 4 is a diagram showing a configuration of a detector of an X-raydetector, according to an example embodiment;

FIG. 5 is a control block diagram of a mobile device including differentcommunication modules, according to an example embodiment;

FIG. 6 is a control block diagram of an X-ray detector includingdifferent communication modules, according to an example embodiment;

FIG. 7A is a control block diagram of a workstation including differentcommunication modules, according to an example embodiment, and FIG. 7Bis a control block diagram of a control panel capable of being pairedwith an X-ray detector, according to an example embodiment;

FIGS. 8A, 8B, and 8C are diagrams showing examples of a screen that maybe displayed when an X-ray detector is tagged with a mobile device,according to an example embodiment;

FIGS. 9A and 9B are diagrams showing examples of a screen that may bedisplayed when a workstation receives identification information of anX-ray detector from a mobile device, according to an example embodiment;

FIGS. 10A and 10B are diagrams showing examples of a screen that may bedisplayed when a tube head unit receives identification information ofan X-ray detector from a mobile device, according to an exampleembodiment;

FIG. 11 is a diagram showing an example in which approval of pairing ofan X-ray detector is finally received from a user, according to anexample embodiment;

FIG. 12 is a diagram showing an example in which identificationinformation of a new X-ray detector is delivered to a workstation pairedwith an X-ray detector, according to an example embodiment;

FIG. 13 is a diagram showing a process in which an X-ray detector and aworkstation are paired, according to another example embodiment;

FIGS. 14 and 15 are control block diagrams of an X-ray detector and aworkstation, according to another example embodiment;

FIGS. 16A and 16B are diagrams showing examples of a screen that may bedisplayed on a display of a workstation when the workstation receives apairing request from an X-ray detector, according to an exampleembodiment;

FIGS. 17A and 17B are diagrams showing examples of a screen that may bedisplayed when a tube head unit receives a pairing request from an X-raydetector, according to an example embodiment;

FIG. 18 is a diagram showing an example of a pairing approval screendisplayed on a mobile device, according to an example embodiment;

FIG. 19 is a control block diagram of an X-ray detector according tostill another example embodiment;

FIG. 20 is a control block diagram of an automatic exposure control(AEC) unit according to an example embodiment;

FIG. 21 is a diagram showing a configuration of an AEC unit according toan example embodiment;

FIG. 22 is a flowchart of a pairing method of an X-ray detector,according to an example embodiment; and

FIG. 23 is a flowchart of a pairing method of an X-ray detector,according to another example embodiment.

DETAILED DESCRIPTION

Hereinafter, example embodiments of an X-ray detector, a mobile device,a workstation, an X-ray imaging apparatus, and a method of pairing anX-ray detector with a workstation will be described in detail withreference to the following drawings.

In the following description, like drawing reference numerals are usedfor like elements, even in different drawings. The matters defined inthe description, such as detailed construction and elements, areprovided to assist in a comprehensive understanding of the exampleembodiments. However, it is apparent that the example embodiments can bepracticed without those specifically defined matters. Also, well-knownfunctions or constructions may not be described in detail because theywould obscure the description with unnecessary detail.

It will be understood that the terms such as “unit,” “-er (-or),” and“module” described in the specification refer to an element forperforming at least one function or operation, and may be implemented inhardware, software, or the combination of hardware and software.

FIGS. 1A and 1B are diagrams showing an exterior appearance of an X-rayimaging apparatus according to an example embodiment.

The exterior appearance shown in FIG. 1A is an example of the X-rayimaging apparatus, which is a ceiling-type X-ray imaging apparatus witha tube head unit (THU) connected to a ceiling.

Referring to FIG. 1A, a guide rail 30 may be installed at a laboratoryceiling on which an X-ray imaging apparatus 1 is disposed, and a tubehead unit (THU) 10 may be connected to a movable carriage 40 movingalong the guide rail 30 and moved to a position corresponding to anobject.

The guide rail 30 may include a first guide rail 31 and a second guiderail 32 that are installed to have a predetermined angle with respect toeach other.

As an example, the first guide rail 31 and the second guide rail 32 maybe installed to be orthogonal to each other.

The first guide rail 31 may be installed at a laboratory ceiling, andthe second guide rail 32 may be mounted on a lower side of the firstguide rail 31 so that the second guide rail 32 may be slid. A rollermovable along the first guide rail 31 may be installed at the firstguide rail 31. The second guide rail 32 may be connected to the rollerto move along the first guide rail 31.

A first direction 01 may be defined as a direction in which the firstguide rail 31 extends, and a second direction D2 may be defined as adirection in which the second guide rail 32 extends. Accordingly, thefirst direction D1 and the second direction D2 may be orthogonal to eachother and parallel with the laboratory ceiling.

The movable carriage 40 is disposed at a lower side of the second guiderail 32 so that the movable carriage 40 may move along the second guiderail 32. A roller provided to move along the second guide rail 32 may beinstalled at the movable carriage 40. Accordingly, the movable carriage40 may move in the first direction D1 together with the second guiderail 32 and move in the second direction D2 along the second guide rail32.

A post frame 50 is connected to the bottom of the movable carriage 40.The post frame 50 may include a plurality of posts 51, 52, 53, 54, and55.

The plurality of posts 51, 52, 53, 54, and 55 are foldably connected toeach other. The post frame 50 may be shortened in an upward direction ofa laboratory or lengthened in a downward direction of the laboratorywhile being fixed to the movable carriage 40.

Because the THU 10 is coupled to the bottom of the post frame 50, aheight of the THU 10 from the ground may be controlled by lengtheningand shortening the post frame 50.

A third direction D3 may be defined as a direction in which the postframe 50 is lengthened or shortened. Accordingly, the third direction D3may be orthogonal to the first direction D1 and the second direction D2.

The THU 10 is a device configured to emit an X-ray toward an object. TheTHU 10 may be an assembly including an X-ray tube that generates anX-ray and a collimator that adjusts an emission range of the generatedX-ray and may be referred to as an X-ray source.

The THU 10 may be connected to the movable carriage 40 through aconnection pipe 75. Various kinds of cables and electric wires thatconnect the THU 10 to other devices may built into the connection pipe75, and also high voltage generated by a high-voltage generator may besupplied to the THU 10 through the connection pipe 75.

A rotatable joint 60 is disposed between the THU 10 and the post frame50. The rotatable joint 60 combines the THU 10 with the post frame 50and supports weight applied to the THU 10.

The rotatable joint 60 may include a first rotatable joint 61 connectedto a lowest post 51 of the post frame 50 and a second rotatable joint 62connected to the THU 10.

The first rotatable joint 61 is configured to rotate about a centralaxis of the post frame 50 that extends in a vertical direction of thelaboratory. Accordingly, the first rotatable joint 61 may rotate on aplane perpendicular to the third direction D3. In this case, arotational direction of the first rotatable joint 61 may be newlydefined, and the newly-defined direction, which is a fourth directionD4, is a rotational direction of an axis parallel with the thirddirection D3.

The second rotatable joint 62 is configured to rotate on a planeperpendicular to the laboratory ceiling. Accordingly, the secondrotatable joint 62 may rotate in a rotational direction of an axisparallel with the first direction D1 or the second direction D2. In thiscase, the rotational direction of the second rotatable joint 62 may benewly defined, and the newly-defined direction, which is a fifthdirection D5, is a rotational direction of an axis extending in thefirst direction D1 or the second direction D2.

The THU 10 may be connected to the rotatable joint 60 to rotatably movein the fourth direction D4 and the fifth direction D5. A tilt angle ofthe THU 10 may be adjusted by rotating the second rotatable joint 62 inthe fifth direction D5.

Also, the THU 10 may be connected to the post frame 50 by the rotatablejoint 60 to linearly move in the first direction D1, the seconddirection D2, and the third direction D3.

A tube motor 90 may be provided to move the THU 10 in the first to fifthdirections D1 to D5. The tube motor 90 may include an encoder thatmeasures the number of rotations.

The tube motor 90 may include a plurality of motors 91, 92, and 93corresponding to respective directions, each of which may be disposed atvarious positions in consideration of design convenience.

For example, the motor 91 that moves the second guide rail 32 in thefirst direction D1 may be disposed in the vicinity of the first guiderail 31, the motor 92 that moves the movable carriage 40 in the seconddirection D2 may be disposed in the vicinity of the second guide rail32, and the motor 93 that increases or decreases the length of the postframe 50 in the third direction D3 may be disposed at the movablecarriage 40.

Also, a motor that rotatably moves the THU 10 in the fourth direction D4may be disposed in the vicinity of the first rotatable joint 61, a motorthat rotatably moves the THU 10 in the fifth direction D5 may bedisposed in the vicinity of the second rotatable joint 62.

Each of the motors may be connected to a power transfer unit to linearlyor rotatably move the THU 10 in the first to fifth directions D1 to D5.The power transfer unit may be a belt and pulley system, a chain andsprocket system, a shaft, or the like that are generally used.

A control panel 80 that provides information to a user and receives acontrol command from the user as an input may be provided at one side ofthe THU 10. Here, the user is a person who takes an X-ray image of anobject using the X-ray imaging apparatus 1, and may be medical staffincluding, but not limited to, a doctor, a radiologist, and a nurse. Theuser may include a person who can use the X-ray imaging apparatus 1.

An imaging table 22 and an imaging stand 21 that may be equipped withthe X-ray detector 200 may be provided at a position adjacent to amovable range of the THU 10.

A detector mounting unit 22 a is formed on the bottom of the imagingtable 22 and is movable in a longitudinal direction (a direction D8) ofthe imaging table 22. The X-ray detector 200 is inserted into thedetector mounting unit 22 a. When an object is placed on the imagingtable 22, the THU 10 and the detector mounting unit 22 a may be moved toa position corresponding to a portion of the object to be imaged. Then,X-ray imaging may be performed.

Also, a detector mounting unit 21 a may be formed on the imaging stand21 to move in a longitudinal direction (a direction D6) of the imagingstand 21. The longitudinal direction of the imaging stand 21 isperpendicular to the longitudinal direction of the imaging table 22. TheX-ray detector 200 is inserted into the detector mounting unit 21 a.When an object is placed in front of the detector mounting unit 21 a,the THU 10 and the detector mounting unit 21 a may be moved to aposition corresponding to a portion of the object to be imaged. Then,X-ray imaging may be performed.

The X-ray imaging apparatus 1 may include a motor for moving thedetector mounting unit 22 a of the imaging table 22 in the direction D8and a motor for moving the detector mounting unit 21 a of the imagingstand 21 in the direction D6.

The X-ray imaging apparatus 1 may include a host device that controlsthe overall operation of the X-ray imaging apparatus 1. As an example,the host device may include a workstation 300 as shown in FIG. 1. Theworkstation 300 may be located in a space that is separated from a spacewhere the THU 10 is placed by a shielding wall B. Also, as anotherexample, the workstation 300 may be implemented as a tablet PC, a laptopcomputer, and a mobile device such as a smartphone.

The workstation 300 may include a display 340 that displays an X-rayimage, a screen for guiding an input of a control command, a variety ofsetting information related to the X-ray imaging apparatus 1, and thelike, and an input interface 350 that receives various kinds of controlcommands related to X-ray imaging from a user as an input.

The display 340 may include one of display panels such as a cathode raytube (CRT), a digital light processing (DLP) panel, a plasma displaypanel, a liquid crystal display (LCD) panel, an electro luminescence(EL) panel, an electrophoretic display (EPD) panel, an electrochromicdisplay (ECD) panel, a light emitting diode (LED) panel, and an organiclight emitting diode (OLED) panel, but is not limited thereto.

The input interface 350 may be implemented as an input device such as akeyboard, a mouse, a trackball, a jog shuttle, and a touch pad. Theinput interface 350 may be implemented as a touch pad. When the inputinterface 350 is disposed on the front of the display 340, the inputinterface 350 may be combined with the display 340 to form a touchscreen.

The X-ray detector 200 may be mounted on the detector mounting unit 21 aof the imaging stand 21 or the detector mounting unit 22 a of theimaging table 22.

Also, one X-ray detector may be selectively used by a plurality of X-rayimaging apparatuses, and one X-ray imaging apparatus may selectively useone of a plurality of X-ray detectors.

Accordingly, a task of pairing an X-ray detector to be used for imagingwith a workstation is performed before taking an X-ray image.

An error may be caused by a user directly entering information forpairing to the workstation, and the user's work load may be increased.Accordingly, the X-ray imaging apparatus according to an exampleembodiment may use a mobile device to simply and accurately pair anX-ray detector with a workstation, thus reducing a possibility of anerror and a user's work load.

The control panel 80 provided at the THU 10 may include an inputinterface 85 (see FIG. 10A) that receives a control command of the useras an input and a display 84 (see FIG. 10A) that displays a screen forguiding input of a control command or a screen for indicating a statusof the X-ray imaging apparatus 1.

The user may manipulate the control panel 80 to enter a control commandfor X-ray imaging or, as described below, to enter a control command forpairing with the X-ray detector 200.

The control panel 80 may deliver a control command entered by the userto the workstation 300 or may directly control the THU 10 or the X-raydetector 200 according to the entered control command. That is, thecontrol panel 80 may perform some or all functions of the workstation300. In this case, the control panel 80 may be included in the hostdevice.

FIGS. 2A to 2C are diagrams showing a process of pairing an X-raydetector with a workstation using a mobile device, according to anexample embodiment, and FIG. 3 is a control block diagram of an X-rayimaging apparatus according to an example embodiment.

A mobile device 100 may be a portable electronic device capable ofcommunication such as a smartphone, a smart watch, smart glasses, atablet PC, and a PDA.

FIG. 2A shows an example in which the mobile device 100 is a smartphone,FIG. 2B shows an example in which the mobile device 100 is a smartwatch, and FIG. 2C shows an example in which the mobile device 100 issmart glasses.

Referring to FIGS. 2A to 2C, when the X-ray detector 200 to be used forX-ray imaging is tagged with the mobile device 100 {circle around (0)},the X-ray detector 200 sends identification information to the mobiledevice 100 {circle around (2)}. Tagging denotes bringing two devicesinto close proximity with each other, that is, a reference distance orless, for short-range wireless communication. A tagging operation mayalso include authentication by a user tagging the X-ray detector 200 tobe used for X-ray imaging.

The identification information sent from the X-ray detector 200 to themobile device 100 may include an address used for communication betweenthe devices, such as an Internet Protocol (IP) address or a Media AccessControl (MAC) address.

Also, the X-ray detector 200 may send detector information in additionto the identification information. The detector information may includeinformation on the X-ray detector 200 such as remaining batterycapacity, size, resolution, pixel size, read-out rate, and calibrationinformation.

When the identification information is received from the X-ray detector200, the mobile device 100 delivers the identification information tothe workstation 300 {circle around (3)}. Also, the detector informationmay also be delivered together with the identification information.

When the identification information is delivered, the workstation 300may send a pairing request to the X-ray detector 200 having thedelivered identification information {circle around (4)}.

When the pairing request is received, the X-ray detector 200 sends aresponse {circle around (5)}. In this case, the X-ray detector 200 andthe workstation 300 are paired and may send and receive signals to andfrom each other. In this example embodiment, the transmission andreception of the request and response may include transmission andreception of signals.

When the X-ray detector 200 and the workstation 300 are paired and startX-ray imaging, the X-ray detector 200 may detect an X-ray, convert thedetected X-ray into X-ray data, and send the X-ray data to theworkstation 300.

Also, when the X-ray detector 200 does not deliver detector informationsuch as size, resolution, pixel size, read-out rate, and calibrationinformation to the workstation 300 through the mobile device 100, theX-ray detector 200 may directly send the detector information afterbeing paired with the workstation 300.

Also, the workstation 300 may send a control signal for controlling anoperation of the X-ray detector 200 to the X-ray detector 200.

When the control panel 80 of the THU 10 is included in the host device,the X-ray detector 200 may send the identification information of theX-ray detector 200 to the control panel 80 rather than the workstation300, and the control panel 80 may send a pairing request to the X-raydetector 200 having the sent identification information, thus enablingthe control panel 80 and the X-ray detector 200 to be paired as shown inFIGS. 2A to 2C.

Referring to FIG. 3, the mobile device 100 according to an exampleembodiment may include a communicator 110, a controller 120, a storage130, a display 140, and an input interface 150.

The communicator 110 may receive identification information from theX-ray detector 200 and may send the received identification informationto the workstation 300.

The communicator 110 may include at least one wireless communicationmodule. When the communicator 110 communicates with the X-ray detector200 or when the communicator 110 communicates with the workstation 300,different types of communication modules or the same type ofcommunication module may be used. The communicator 110 will be describedbelow in detail.

The display 140 may display a screen for informing a user that themobile device 100 has been connected with the X-ray detector 200, andthe input interface 150 may receive a control command of the user as aninput.

The controller 120 controls an operation of the mobile device 100. Thecontroller 120 may control the communicator 110 to send detectorinformation to the workstation 300 or control the display 140 to displaya connection screen or the detector information.

The controller 120 may include a memory that stores a program forperforming an operation that has been described or will be described anda processor that executes the program stored in the memory.

The controller 120 may include a plurality of processors or a pluralityof memories depending on performed operations or processor capacity.

Also, the controller 120 may be physically separated from other elementssuch as the communicator 110 or the display 140 or may be integratedinto a single chip.

The storage 130 may be a non-volatile memory or a volatile memory. Datatemporarily needed may be stored in the volatile memory, and data neededuntil a deletion command is input may be stored in the non-volatilememory. For example, the identification information of the X-raydetector 200 or the identification information of the workstation 300may be stored in the non-volatile memory and used when needed.

The storage 130 may share the memory with the controller 120. That is, aprogram executed by the processor of the controller 120 may be stored inthe memory of the storage 130.

The mobile device 100 may be sold as an element of the X-ray imagingapparatus 1. A user may install a program for executing theabove-described operation and an operation to be described below inanother mobile device carried by the user. Accordingly, the mobiledevice 100 may or may not be an element of the X-ray imaging apparatus1.

The X-ray detector 200 according to an example embodiment includes acommunicator 210, a controller 220, a storage 230, and a detector 240.

The communicator 210 may send detector information by communicating withthe mobile device 100, receive a pairing request by communicating withthe workstation 300, and send X-ray data to the workstation 300 inresponse to the pairing request after pairing.

The communicator 210 may include at least one wireless communicationmodule. When the communicator 210 communicates with the mobile device100 or when the communicator 110 communicates with the workstation 300,different types of communication modules or the same type ofcommunication module may be used. The communicator 210 will be describedbelow in detail.

The storage 230 may be a non-volatile memory or a volatile memory. Forexample, the identification information of the X-ray detector 200 or theidentification information of the workstation 300 may be stored in thenon-volatile memory and used when needed.

Also, the storage 230 may temporarily or non-temporarily store X-raydata acquired by the detector 240.

The controller 220 may control the communicator 210 and the detector240.

For example, when the communicator 210 is tagged by the mobile device100, the controller 220 may control the communicator 210 to sendidentification information to the mobile device 100. When a pairingrequest is received from the workstation 300, the controller 220 maycontrol the communicator 210 to send detector information to theworkstation 300. Also, after the detector 240 detects an X-ray, thecontroller 220 may control the communicator 210 to send X-ray data tothe workstation 300.

Also, the controller 220 may activate the detector 240. When an X-ray isincident on the detector 240, the controller 220 may control thedetector 240 to detect the X-ray and convert the detected X-ray into anelectric signal.

FIG. 4 is a diagram showing a configuration of a detector of an X-raydetector, according to an example embodiment.

The detector 240 may include a light receiving device 241 that detectsan X-ray and generates an electrical signal and a read-out circuit 242that reads out the generated electrical signal. Hereinafter, theelectric signal that is read out and output by the read-out circuit 242will be referred to as X-ray data.

The light receiving device 241 may be made with a single crystalsemiconductor material to ensure high resolution, high response speed,and a high dynamic area even under conditions of low energy and a smalldose of X-rays. The single crystal semiconductor material may be Ge,CdTe, CdZnTe, or GaAs.

The light receiving device 241 may be in the form of a PIN photodiode.The PIN photodiode is fabricated by bonding a p-type semiconductorsubstrate 241 c of a 2D array structure under an n-type semiconductorsubstrate 241 a with high resistance.

The read-out circuit 242, which is fabricated according to acomplementary metal-oxide semiconductor (CMOS) process, is in the formof a 2D array structure and may be combined with the p-typesemiconductor substrate 241 c of the light receiving device 241 in unitsof pixels. In this case, a flip-chip bonding (FCB) method of formingbumps 243 with solder (PbSn), indium (In), or the like and thenreflowing, applying heat, and applying pressure may be used as thecombining method.

As described above, the X-ray detector 200 may be mounted on thedetector mounting unit 21 a provided at the imaging stand 21 or mountedon the detector mounting unit 22 a provided at the imaging table 22.Alternatively, the X-ray detector 200 may be used portably rather thanbeing mounted on a mounting unit.

A structure of the above-described X-ray detector is an example that maybe applied to the X-ray imaging apparatus 1. An example of the X-rayimaging apparatus 1 or an example of the X-ray detector 200 is notlimited to the structure.

For example, the X-ray detector 200 may have various structuresdepending on a material configuration method, a method of converting adetected X-ray into an electric signal, and a method of acquiring anelectric signal. The above-described structure is an example of thedetector 240 included in the X-ray detector 200. A structure of thedetector 240 is not limited to the above-described example.

The X-ray detector 200 may include in the X-ray imaging apparatus 1 andsold or may be sold separately from the X-ray imaging apparatus 1 andthen used after being registered. Accordingly, the X-ray imagingapparatus 1 may or may not include the X-ray detector 200.

Referring to FIG. 3 again, the workstation 300 includes a communicator310, a controller 320, a storage 330, a display 340, and an inputinterface 350.

The communicator 310 may receive the identification information of theX-ray detector 200 from the mobile device 100 and may send a pairingrequest to the X-ray detector 200 having the received identificationinformation. Also, after the workstation 300 is paired with the X-raydetector 200, the communicator 310 may receive X-ray data from the X-raydetector 200.

When the communicator 310 receives the identification information of theX-ray detector 200 from the mobile device 100, the controller 320 maycontrol the communicator 310 to send the pairing request to the X-raydetector 200 having the received identification information.

Also, the controller 320 may process X-ray data received from the X-raydetector 200 to generate an X-ray image from which a lesion may beidentified.

The storage 330 may store the identification information of the X-raydetector 200 received from the mobile device 100. Also, the storage 330may store the X-ray data received from the X-ray detector 200, the X-rayimage generated by processing the X-ray data, and the like.

FIG. 5 is a control block diagram of a mobile device including differentcommunication modules, according to an example embodiment, FIG. 6 is acontrol block diagram of an X-ray detector including differentcommunication modules, according to an example embodiment, FIG. 7A is acontrol block diagram of a workstation including different communicationmodules, according to an example embodiment, and FIG. 7B is a controlblock diagram of a control panel capable of being paired with an X-raydetector, according to an example embodiment.

Referring to FIG. 5, the communicator 110 of the mobile device 100 mayinclude a first communicator 111 that communicates with the X-raydetector 200 and a second communicator 112 that communicates with theworkstation 300.

Referring to FIG. 6, the communicator 210 of the X-ray detector 200 mayinclude a first communicator 211 that communicates with the mobiledevice 100 and a second communicator 212 that communicates with theworkstation 300.

Referring to FIG. 7A, the communicator 310 of the workstation 300 mayinclude a first communicator 311 that communicates with the mobiledevice 100 and a second communicator 312 that communicates with theX-ray detector 200.

Also, when the control panel 80 is included in a host device so that theX-ray detector 200 and the control panel 80 may be paired, the controlpanel 80 may include a communicator 81 that communicates with the mobiledevice 100 and the X-ray detector 200, and a controller 82 may controlan operation of performing pairing with the X-ray detector 200, as shownin FIG. 7B.

Also, the storage 83 may store the identification information of theX-ray detector 200 that is received from the mobile device 100.

Also, the communicator 81 may include a first communicator 81 a thatcommunicates with the mobile device 100 and a second communicator 81 bthat communicates with the X-ray detector 200.

In the following example embodiment, pairing between the workstation 300and the X-ray detector 200 will be described in detail. The descriptioncan be equally applicable to pairing between the X-ray detector 200 andthe control panel 80 of the THU 10.

The mobile device 100 and the X-ray detector 200, the mobile device 100and the workstation 300, or the X-ray detector 200 and the workstation300 may be mutually connected through short-range wirelesscommunication. Examples of short-range communication technology that maybe applied to this example embodiment include Wireless LAN, Wi-Fi,Bluetooth, ZigBee, Wi-Fi Direct (WFD), ultra wideband (UWB), InfraredData Association (IrDA), Bluetooth Low Energy (BLE), and Near FieldCommunication (NFC).

For example, the mobile device 100 and the X-ray detector 200 mayperform communication by employing one of short-range wirelesscommunication methods in which data may be sent or received throughtagging, such as an NFC method and a radio frequency identification(RFID) method.

In this case, the first communicator 111 of the mobile device 100 mayinclude any one or any combination of devices capable of receiving orreading signals over a short distance, such as an NFC module and an RFIDreader, and the first communicator 211 of the X-ray detector 200 mayinclude any one or any combination of devices capable of sending orreading signals over a short distance, such as an NFC module and an RFIDtag.

Here, the modules or the tags that are included in the firstcommunicators 111 and 211 correspond to each other. That is, when thefirst communicator 111 of the mobile device 100 includes an NFC module,the first communicator 211 of the X-ray detector 200 also includes anNFC module. When the first communicator 111 of the mobile device 100includes an RFID reader, the first communicator 211 of the X-raydetector 200 includes an RFID tag.

NFC communication is a non-contact communication technology for sendingand receiving radio data over a short distance of 10 cm or lessaccording to the NFC standard, and uses a frequency band of 13.56 MHz.

NFC communication enables bi-directional communication. That is, the NFCmodule may perform functions of both an NFC reader and an NFC tag.Accordingly, the NFC module included in the first communicator 111 ofthe mobile device 100 may send data to the NFC module included in thefirst communicator 211 of the X-ray detector 200.

The NFC module may include an antenna that sends and receives signals, amodulator that modulates a signal to be sent through the antenna, and ademodulator that demodulates a signal received through the antenna.However, the NFC module included in the first communicator 211 of theX-ray detector 200 may include only an NFC tag.

The identification information of the X-ray detector 200 may be sent tothe mobile device 100 through the NFC module. The detector informationsuch as size, resolution, pixel size, read-out rate, and calibrationinformation of the X-ray detector 200 may be further sent.

When there is no need for the mobile device 100 to send signals to theX-ray detector 200, the first communicator 211 of the X-ray detector 200may include only an NFC tag in which the identification information hasbeen recorded.

RFID communication is a non-contact communication technology for sendingand receiving radio data over a distance of 1 to 2 m, and uses afrequency band of 900 MHz.

Because RFID communication supports only a read function, unlike NFCcommunication, an RFID reader included in the first communicator 111 ofthe mobile device 100 reads information recorded in an RFID tag includedin the second communicator 212 of the X-ray detector 200 when the mobiledevice 100 and the X-ray detector 200 send and receive data using RFIDcommunication.

Accordingly, the identification information of the X-ray detector 200may be recorded in the RFID tag included in the second communicator 212of the X-ray detector 200, and the detector information such as size,resolution, pixel size, read-out rate, and calibration information ofthe X-ray detector 200 may also be recorded.

However, the NFC and RFID methods are examples of communication methodsused by the mobile device 100 and the X-ray detector 200 to send andreceive signals. Signals may be sent and received using othercommunication methods.

Also, the mobile device 100 and the workstation 300 may send and receivedata through short-range wireless communication.

For example, the second communicator 112 of the mobile device 100 mayinclude any one or any combination of devices capable of sending signalsa short distance, such as an NFC module, a Bluetooth module, and abeacon.

Also, the first communicator 311 of the workstation 300 may include anyone or any combination of devices capable of receiving signals over ashort distance, such as an NFC module, a Bluetooth module, and a BLEmodule.

Here, a module included in the first communicator 311 of the workstation300 corresponds to that of the second communicator 112 of the mobiledevice 100. That is, when the second communicator 112 of the mobiledevice 100 includes an NFC module, the first communicator 311 of theworkstation 300 also includes an NFC module. When the secondcommunicator 112 of the mobile device 100 includes a Bluetooth module,the first communicator 311 of the workstation 300 also includes aBluetooth module. When the second communicator 112 of the mobile device100 includes a beacon, the first communicator 311 of the workstation 300includes a BLE module.

An example in which the second communicator 112 of the mobile device 100includes a beacon and the first communicator 311 of the workstation 300includes a BLE module will be described in detail.

The beacon is a short-range wireless communication device based on aBluetooth 4.0 or BLE protocol, which may send signals to a BLE modulethat is located within about 50 m to 70 m without a separate pairingstep.

The beacon transmits identification information (ID) of the X-raydetector 200 a range of about 50 m to 70 m. The BLE module of theworkstation 300 that has entered the range recognizes the beacon andreceives the identification information transmitted by the beacon.

The BLE module does not have a large influence on a battery capacityalthough a Bluetooth function is always turned on because the BLE moduleoperates with low power. Accordingly, when a user tags the X-raydetector 200 with the mobile device 100 and moves to a position within arange of the workstation 300 in a state in which the BLE module of theworkstation 300 is always turned on, the workstation 300 may receive abeacon signal transmitted by the mobile device 100 and acquire theidentification information of the X-ray detector 200 included in thebeacon signal.

Here, the mobile device 100 may deliver the identification informationof the X-ray detector received by the first communicator 111 to theworkstation 300 through the second communicator 112.

Likewise, the BLE communication method is also an example of acommunication method used by the mobile device 100 and the workstationto send and receive signals. Signals may be sent and received usingother communication methods.

When the first communicator 311 of the workstation 300 acquires theidentification information of the X-ray detector 200 from the mobiledevice 100, the second communicator 312 of the workstation 300 sends apairing request to the X-ray detector 200.

The second communicator 212 of the X-ray detector 200 sends a responseto the second communicator 312 of the workstation 300 when the pairingrequest is received, and the pairing between the X-ray detector 200 andthe workstation 300 is completed. Here, the completion of the pairingmeans that the X-ray detector 200 and the workstation 300 may send andreceive signals.

For example, the X-ray detector 200 and the workstation 300 maycommunicate through WFD. In this case, the second communicator 212 ofthe X-ray detector 200 and the second communicator 312 of theworkstation 300 may each include a WFD module.

Also, the communicator 310 of the workstation 300 may further include awireless communication module for sending and receiving signals to andfrom any one or any combination of a base station of a mobilecommunication network, a distant electronic device, and a server such asa picture archiving and communication system (PACS).

An example in which the communication method between the mobile device100 and the X-ray detector 200, the communication method between themobile device 100 and the workstation 300, and the communication methodbetween the workstation 300 and the X-ray detector 200 are differentfrom each other has been described above, but example embodiments arenot limited thereto. Accordingly, some or all of the methods may employthe same communication method.

When the X-ray detector 200 and the workstation 300 are paired, theX-ray detector 200 may send detector information to the workstation 300,and the workstation 300 may send a control signal for controlling theX-ray detector 200.

When X-ray imaging is started, the X-ray detector 200 detects an X-rayand sends X-ray data acquired from the detected X-ray. The controller320 of the workstation 300 may generate an X-ray image from which alesion can be identified by processing the X-ray data using the detectorinformation. The display 340 may display the generated X-ray image. Theinput interface 350 may receive a control command associated with X-rayimaging and X-ray image generation from a user as an input.

The storage 330 may temporarily or non-temporarily store identificationinformation, detector information, X-ray data, and an X-ray image of theX-ray detector 200.

Also, the communicator 310 may send the generated X-ray image to a PACSor other terminals. In this case, the above-described wirelesscommunication module may be used.

FIGS. 8A, 8B, and 8C are diagrams showing examples of a screen that maybe displayed when an X-ray detector is tagged with a mobile device,according to an example embodiment, FIGS. 9A and 9B are diagrams showingexamples of a screen that may be displayed when a workstation receivesidentification information of an X-ray detector from a mobile device,according to an example embodiment, and FIGS. 10A and 10B are diagramsshowing examples of a screen that may be displayed when a THU receivesidentification information of an X-ray detector from a mobile device,according to an example embodiment.

As described above, when the X-ray detector 200 is tagged with themobile device 100, the identification information of the X-ray detector200 is sent to the mobile device 100. As shown in FIG. 8A, a receptionscreen 140 a that informs that the identification information has beenreceived from the X-ray detector 200 may be displayed on the display 140of the mobile device 100, and the received identification informationmay also be displayed in the reception screen 140 a.

Alternatively, recognition identification information for facilitatingrecognition of the X-ray detector by a user, such as a model name of theX-ray detector or a name set by the user may be displayed rather thanidentification information used to perform pairing with the workstation,such as an IP address or MAC address.

The recognition identification information may be sent by the X-raydetector 200 together with the identification information for pairing ormay be mapped to the identification information for pairing andprestored in the storage 130 of the mobile device 100.

The user may confirm that the identification information has been sentfrom the X-ray detector 200 by viewing the reception screen 140 a andmay move to the vicinity of the workstation 300 while carrying themobile device 100. Alternatively, the user may not move depending onwhether the X-ray detector 200 is mounted on the detector mounting unit21 a or 22 a, a distance between the workstation 300 and the X-raydetector 200, and the like, and the workstation 300 and the mobiledevice 100 have only to be positioned in a communicable distance.

For example, assuming that the communicator 110 of the mobile device 100includes a beacon and that the communicator 310 of the workstation 300includes a BLE module, the identification information of the X-raydetector 200 may be acquired from the mobile device 100 as long as auser who carries the mobile device 100 is positioned within a distanceof about 50 m to 70 m from the workstation 300.

Alternatively, as shown in FIG. 8B, a pairing approval screen 140 c forreceiving an input on whether the pairing is approved from the user maybe displayed on the display 140 of the mobile device 100. When the userselects a “yes” button 140 c-1, the identification information of theX-ray detector 200 may be delivered to the workstation 300. When theuser selects a “no” button 140 c-2, the identification information ofthe X-ray detector 200 may not be delivered to the workstation 300.

Alternatively, when the X-ray detector 200 sends detector informationsuch as battery capacity, size, read-out rate, resolution, calibrationinformation, and pixel size to the mobile device 100 in addition to itsown identification information, the detector information may bedisplayed on the pairing approval screen 140 c as shown in FIG. 8C. Theuser may confirm the detector information and determine whether theX-ray detector is suitable for X-ray imaging to be performed by theX-ray detector and confirm the detector information.

When the user determines to pair the X-ray detector and the workstation,the user may manipulate the input interface 150 to select the “yes”button 140 c-1. When the user determines not to perform pairing, theuser may manipulate the input interface 150 to select the “no” button140 c-2.

When the X-ray detector 200 sends the detector information to the mobiledevice 100, the mobile device 100 may deliver the detector informationto the workstation 300 together with the identification information ormay deliver only the identification information to the workstation 300.

When the mobile device 100 delivers the identification informationreceived from the X-ray detector 200 to the workstation 300, a receptionscreen 340 a that informs a user that the identification information hasbeen received from the mobile device 100 may be displayed on the display340 of the workstation 300 as shown on the left side of FIG. 9A.

Even when a user does not perform a separate operation, the workstation300 may send a pairing request to the X-ray detector having the receivedidentification information. In this case, a pairing request screen 340 bthat informs a user that the pairing request has been received may bedisplayed on the display 340. The user may recognize a current status byviewing the screens 340 a and 340 b displayed on the display 340.

Alternatively, as shown in FIG. 9B, before a pairing request is sent, apairing approval screen 140 c for receiving an input about whether thepairing is approved from a user may be displayed on the display 340.When the user selects a “yes” button 340 c-1, the workstation 300 maysend a pairing request to the X-ray detector. When the user selects a“no” button 340 c-2, the workstation 300 may enter a standby state inwhich the workstation 300 waits for identification information from themobile device 100 to be received rather than sending a pairing request.

FIGS. 9A and 9B show an example in which an IP address, which isidentification information for pairing, is displayed on the screen 340b. However, recognition identification information may be displayed. Forexample, when a user wrongly performs tagging, that is, when anotherX-ray detector is tagged instead of an X-ray detector to be originallyused, the user may confirm the wrong tagging by viewing the recognitionidentification information displayed on the screen 340 b and selectingthe “no” button 340 c-2.

When the control panel 80 of the THU 10 and the X-ray detector 200 arepaired, the mobile device 100 may deliver the identification informationof the X-ray detector 200 to the control panel 80. In this case, asshown in FIG. 10A, a reception screen 84 a that informs the user thatthe identification information has been received from the mobile devicemay be displayed on the display 84 of the control panel 80.

The control panel 80 may automatically send a pairing request to theX-ray detector 200 having the received identification information. Inthis case, a pairing request screen 84 b that informs the user that thepairing request has been received may be displayed on the display 84.The user may recognize a current status by viewing the screens 84 a and84 b displayed on the display 84.

Alternatively, as shown in FIG. 10B, a pairing approval screen 84 c maybe displayed on the display 84 before a pairing request is sent, thusenabling the user to select whether to send a pairing request.

When a user selects a “yes” button 84 c-1, the control panel 80 may senda pairing request to an X-ray detector. When the user selects a “no”button 84 c-2, the control panel 80 may wait until new identificationinformation is received instead of sending a pairing request.

Pairing between the X-ray detector 200 and the workstation 300 orbetween the X-ray detector 200 and the control panel 80 may be completedonly when the user approves the pairing. This will be described belowwith reference to FIG. 11.

FIG. 11 is a diagram showing an example in which approval of pairing ofan X-ray detector is finally received from a user, according to anexample embodiment.

As shown in FIG. 11, the workstation 300 sends a pairing request to theX-ray detector 200 {circle around (1)}. When the X-ray detector 200sends a pairing response to the workstation 300, pairing is notimmediately completed {circle around (2)}, and the workstation 300 maysend a pairing approval request to the mobile device 100 {circle around(3)}. This is so that final approval of the pairing between the X-raydetector 200 and the workstation 300 may be received from a user.

The mobile device 100 may display a screen such as the above-describedexample shown in FIG. 8B or 8C to provide the user with informationregarding the X-ray detector 200 with which the workstation 300 intendsto be paired. When the user inputs a pairing approval command, themobile device 100 sends a pairing approval signal to the workstation 300{circle around (4)}.

When the pairing approval signal is sent from the mobile device 100, theworkstation 300 and the X-ray detector 200 are paired and may send andreceive signals to and from each other {circle around (5)}.

That is, according to this example embodiment, even though a user doesnot input a separate command other than tagging or moving to a positionwithin a communication distance, it is possible to automatically performpairing between the X-ray detector 200 and a host device (a workstationor a control panel). It is also possible to prevent unintended pairingby asking the user whether to approve the pairing before theidentification information of the X-ray detector 200 is delivered fromthe mobile device 100 to the host device, before the host device sends apairing request to the X-ray detector 200, or after the X-ray detector200 responds to the pairing request of the host device.

FIG. 12 is a diagram showing an example in which identificationinformation of a new X-ray detector is delivered to a workstation pairedwith an X-ray detector, according to an example embodiment.

Referring to FIG. 12, while the workstation 300 is paired with a firstX-ray detector 200-1 {circle around (1)}, the mobile device 100 maydeliver new identification information to the workstation 300 {circlearound (2)}. Here, the new identification information is identificationinformation of an X-ray detector other than the first X-ray detector200-1. In this example, the identification information refers toidentification information of a second X-ray detector 200-2.

Also, when the second X-ray detector 200-2 is tagged with the mobiledevice 100, the mobile device 100 may acquire the identificationinformation of the second X-ray detector 200-2.

Each of the first X-ray detector 200-1 and the second X-ray detector200-2 corresponds to the X-ray detector 200 according to theabove-described example embodiment, and the terms “first” and “second”only refer to an order in which the detectors are paired with theworkstation 300.

The first X-ray detector 200-1 and the second X-ray detector 200-2 havethe above-described configuration and only perform the above-describedoperation, and the first X-ray detector 200-1 and the second X-raydetector 200-2 may have different types of detector information ordifferent models.

When the new identification information is delivered, the workstation300 releases the previous pairing {circle around (3)}. That is, theworkstation 300 releases the pairing with the first X-ray detector200-1.

When the workstation 300 sends a pairing request to the second X-raydetector 200-2 {circle around (4)} and the second X-ray detector 200-2responds to the request, the workstation 300 and the second X-raydetector 200-2 are paired {circle around (5)}.

In summary, whenever the workstation 300 receives new identificationinformation from the mobile device 100, the workstation 300 releases theprevious pairing and attempts a new pairing. When new identificationinformation is again received from the mobile device 100 after theworkstation 300 is paired with the second X-ray detector 200-2, theworkstation 300 may release the pairing with the second X-ray detector200-2 and retry a new pairing.

FIG. 13 is a diagram showing a process in which an X-ray detector and aworkstation are paired, according to another example embodiment, andFIGS. 14 and 15 are control block diagrams of an X-ray detector and aworkstation, according to another example embodiment. Even in thisexample embodiment, default elements, such as a THU, an imaging stand,an imaging table, and a mounting unit, of the X-ray imaging apparatusmay be the same as those in the above example embodiment.

According to another example embodiment, an X-ray emitted from the THU10 may activate an X-ray detector or a pairing operation of the X-raydetector.

Referring to FIG. 13, when an X-ray from the THU 10 is incident on anX-ray detector 400 {circle around (1)}, the X-ray detector 400 sensesthe X-ray {circle around (2)} and sends a pairing request to aworkstation 500. When the workstation 500 responds to the pairingrequest {circle around (4)}, the X-ray detector 400 and the workstation500 are paired and may send and receive signals to and from each other.

That is, in this example embodiment, an X-ray incident on the X-raydetector 400 may act as a trigger signal that activates the X-raydetector 400. Here, activation of the X-ray detector 400 means that theX-ray detector 400 may send a pairing request to the workstation 500.That is, the activation may refer to activation of a communicator 410.

Alternatively, the activation of the X-ray detector 400 may includeturning the X-ray detector 400 on. In this case, when a sensor 460 thatis always turned on senses incidence of an X-ray, a detector 440 may beactivated and generate X-ray data, and the communicator 410 may beactivated and send a pairing request to the workstation 500.

The X-ray data generated by the detector 440 may be stored in a storage430. When the X-ray detector 400 and the workstation 500 are paired, thecommunicator 410 may send the X-ray data stored in the storage 430 tothe workstation 500. Accordingly, even when X-ray imaging is startedbefore the X-ray detector 400 and the workstation 500 are paired, X-raydata may be sent to the workstation 500 without loss.

Alternatively, an X-ray emission for activating the communicator 410 mayprecede an X-ray emission for actual X-ray imaging. The X-ray emissionmay be performed with low dose. After the communicator 410 of the X-raydetector 400 is activated and the pairing between the X-ray detector 400and the workstation 500 is achieved, the actual X-ray imaging may beperformed. Here, the preceding X-ray emission may be a pre-shot that isprovided to control X-ray exposure parameters according tocharacteristics of an object.

Referring to FIG. 14, the X-ray detector 400 according to anotherexample embodiment includes the communicator 410 that communicates withthe workstation 500 to send and receive signals, a controller 420 thatcontrols an operation of the X-ray detector 400, the storage 430 thatstores identification information and X-ray data of the workstation 500,the detector 440 that detects an X-ray and converts the detected X-rayinto X-ray data, and the sensor 460 that senses incidence of an X-ray.

The communicator 410 may include a communication module that performsshort-range wireless communication. For example, the communicator 410may employ WFD to communicate with the workstation 500. However, thecommunication method employed by the communicator 410 is not limited toWFD. The communicator 410 may employ another short-range communicationmethod such as Wireless LAN, Wi-Fi, Bluetooth, ZigBee, UWB, IrDA, BLE,and NFC, and may include a communication module corresponding to theemployed communication method.

A description of the detector 440 is the same as that of the detector240 shown in FIG. 4 and thus will be omitted herein.

The sensor 460 may include a sensor capable of sensing an X-ray. As anexample, the sensor 460 may include an ionization chamber used as anautomatic exposure control (AEC) sensor.

The ionization chamber is filled with gas that interacts with an X-rayand generates photoelectrons, Auger electrons, or fluorescence photons.Helium, Nitrogen, Neon, Argon, Krypton, Xenon, or the like may beemployed as the gas filling the ionization chamber.

When an X-ray interacts with the gas filling the ionization chamber andan electric current is generated, the controller 420 may determine thatthe X-ray is incident and may control the communicator 410 to send apairing request to the workstation 500.

To this end, identification information, such as an IP address or MACaddress, of the workstation 500 may be prestored in the storage 430.When an X-ray is incident on the X-ray detector 200, the communicator410 may send a pairing request to the workstation 500 having theidentification information stored in the storage 430.

Alternatively, the communicator 410 may include a BLE module or beaconand transmit a signal including the identification information of theX-ray detector 400 within a range instead of specifying a target thatwill receive the signal. The workstation 500 located in the range mayacquire the identification information of the X-ray. The workstation 500that has acquired the identification information of the X-ray detector400 may send a pairing request to the X-ray detector 400.

In this case, a communication module for sending the identificationinformation of the X-ray detector 400 to the workstation 500 may bedifferent from or the same as a communication module for sending andreceiving signals between the X-ray detector 400 and the workstation 500that are paired.

For example, when the communication modules are different, a beacon orBLE module may be used as the communication module for sending theidentification information of the X-ray detector 400 to the workstation500, and a WFD module may be used as the communication module forsending and receiving signals between the X-ray detector 400 and theworkstation 500.

Referring to FIG. 15, the workstation 500 according to an exampleembodiment includes a communicator 510 that communicates with the X-raydetector 400 to send and receive signals, a controller 520 that controlsan operation of the workstation 500, a storage 530 that storesidentification information and X-ray image signals of the workstation500, a display 540, and an input interface 550.

The communicator 510 may include a communication module that performsshort-range wireless communication. For example, the communicator 510may employ WFD to communicate with the X-ray detector 400. However, thecommunication method employed by the communicator 510 is not limitedthereto. The communicator 510 may employ another short-rangecommunication method such as Wireless LAN, Wi-Fi, Bluetooth, ZigBee,UWB, IrDA, BLE, and NFC, and may include a communication modulecorresponding to the employed communication method.

However, the communicator 510 has a communication module correspondingto the communication module included in the communicator 410 of theX-ray detector 400. For example, when the communicator 410 of the X-raydetector 400 includes a beacon or BLE module and a WFD module, thecommunicator 510 of the workstation 500 may include a BLE module and aWFD module.

Also, the communicator 510 may further include a wireless communicationmodule for sending and receiving signals to and from any one or anycombination of a base station of a mobile communication network, anexternal device, and a server such as a PACS.

When a pairing request is received from the X-ray detector 400, thecommunicator 510 finishes a pairing process in response to the request.When the pairing is completed, the workstation 500 and the X-raydetector may send and receive signals to and from each other.

Also, when the identification information of the X-ray detector 400 isreceived from the X-ray detector 400, the workstation 500 may send apairing request to the X-ray detector 400 corresponding to theidentification information.

When X-ray imaging is started, the communicator 410 of the X-raydetector 400 sends X-ray data acquired from a detected X-ray to theworkstation 500. The communicator 510 of the workstation 500 may receivethe X-ray data. The controller 520 may generate an X-ray image fromwhich a lesion can be identified by processing the received X-ray datausing detector information. The display 540 may display the generatedX-ray image, and the input interface 550 receives a control commandassociated with X-ray imaging and X-ray image generation from a user asan input.

The storage 530 may temporarily or non-temporarily store identificationinformation, detector information, X-ray data, and an X-ray image of theX-ray detector 200.

Also, the communicator 510 may send the generated X-ray image to a PACSor other terminals.

FIGS. 16A and 16B are diagrams showing examples of a screen that may bedisplayed on a display of a workstation when the workstation receives apairing request from an X-ray detector, according to an exampleembodiment.

When the X-ray detector 400 sends a pairing request to the workstation500, a reception screen 540 a that informs a user that the pairingrequest has been received from the X-ray detector 400 may be displayedon the display 540 of the workstation 300 as shown on the left side ofFIG. 16A.

Even when the user does not perform a separate operation, theworkstation 500 may automatically send a pairing response to approve thepairing. In this case, an approval screen 540 b that informs the userthat the pairing has been approved may be displayed on the display 540.The user may recognize a current status by viewing the screens 540 a and540 b displayed on the display 540.

Alternatively, as shown in FIG. 16B, an approval request screen 540 cmay be displayed on the display 540 before the pairing is approved, thusallowing the user to select whether to approve the pairing. When theuser selects a “yes” button 540 c-1, the workstation 500 may send apairing response to the X-ray detector 400, and thus the pairing may becompleted. When the user selects a “no” button 540 c-2, the workstation500 does not send a pairing response to the X-ray detector 400.

FIGS. 16A and 16B show examples in which IP addresses, each of which isidentification information for pairing, are displayed on the screens 540b and 540 c. However, recognition identification information may also bedisplayed. For example, when an X-ray detector that is not suitable forX-ray imaging intended to be performed is mounted, a user may confirmthat the unsuitable X-ray detector has been mounted by viewingrecognition identification information displayed on the screens 540 band 540 c and selecting the “no” button 540 c-2.

Also, when the X-ray detector 400 sends its own identificationinformation, a screen that asks the user whether to send a pairingrequest to the X-ray detector 400 may be displayed on the display 540 ofthe workstation 500 to receive the user's selection or a screen thatinforms the user that pairing is being requested may be displayed on thedisplay 540 while sending a pairing request without the user'sselection.

FIGS. 17A and 17B are diagrams showing examples of a screen that may bedisplayed when a THU receives a pairing request from an X-ray detector,according to an example embodiment, and FIG. 18 is a diagram showing anexample of a pairing approval request screen displayed on a mobiledevice, according to an example embodiment.

Like the aforementioned example embodiment, when a control panel 600 ofthe THU 10 is included in a host device to perform some or all functionsof the workstation 500, the X-ray detector 400 may send a pairingrequest to the control panel 600. When the control panel 600 that hasreceived the pairing request responds to the pairing, the pairingbetween the X-ray detector 400 and the control panel 600 may beimmediately approved and completed.

Alternatively, as shown in FIG. 17A, a reception screen 640 a thatinforms a user that a pairing request has been received from the X-raydetector 400 may be displayed on the display 640 of the control panel600. In this case, the control panel 600 may also approve the pairingwithout the user's manipulation. At this point, an approval screen 640 bthat informs the user that the pairing has been approved may bedisplayed on the display 640 of the control panel 600.

Alternatively, as shown in FIG. 17B, a pairing approval request screen640 c may be displayed on the display 640 before the pairing isapproved, thus allowing the user to approve the pairing. When the usermanipulates the input interface 650 to select a “yes” button 640 c-1,the pairing is approved, and the control panel 600 sends a response tothe X-ray detector 400. When the user selects a “no” button 640 c-2, thecontrol panel 600 does not send a response.

Alternatively, when a pairing request is received from the X-raydetector 400, the workstation 500 or the control panel 600 may send apairing approval request to a mobile device 700. In this case, as shownin FIG. 18, a pairing approval request screen 740 c may be displayed ona display 740 of the mobile device 700.

Information regarding the mobile device 700 may be prestored in theworkstation 500. That is, the workstation 500 may send a pairingapproval request to the mobile device 700 having the informationprestored in the workstation 500.

When a user manipulates an input interface 750 to select a “yes” button740 c-1, the mobile device 700 may send a pairing approval signal to theworkstation 500 or the control panel 600.

When the workstation 500 or the control panel 600 receives the pairingapproval signal, the pairing between the X-ray detector 400 and theworkstation 500 or the control panel 600 is completed. When theworkstation 500 or the control panel 600 has not sent a pairing responseto the X-ray detector 400 upon reception of the pairing approval signal,the workstation 500 or the control panel 600 may send the pairingresponse after receiving the pairing approval signal. When the pairingresponse has already been sent, the pairing is completed and signals maybe sent or received.

When the user selects a “no” button 740 c-2, a pairing refusal signalmay be sent to the workstation 500 or the control panel 600. In thiscase, although the workstation 500 or the control panel 600 has sent thepairing response to the X-ray detector 400, the pairing is notcompleted.

In the aforementioned example embodiment, the X-ray detector 400 may notinclude the sensor 460. In this case, when the detector 440 detects anX-ray and generates X-ray data, the controller 420 activates thecommunicator 410 to send a pairing request or identification informationto the workstation 500.

Regardless of whether the sensor 460 is included, incidence of an X-rayacts as a trigger signal or an activation signal. However, incidence ofan X-ray is sensed by the sensor 460 when the sensor 460 is included,and the incidence of the X-ray is sensed by the detector 440 when thesensor 460 is not included. An example in which an X-ray detector doesnot include the sensor will be described below.

FIG. 19 is a control block diagram of an X-ray detector according tostill another example embodiment, FIG. 20 is a control block diagram ofan AEC unit according to an example embodiment, and FIG. 21 is a diagramshowing a configuration of an AEC unit according to an exampleembodiment.

Referring to FIG. 19, an X-ray detector 800 according to still anotherexample embodiment includes a communicator 810 that communicates withthe workstation 500 and an AEC unit 900, a controller 820 that controlsan operation of the X-ray detector 800, a storage 830 that storesidentification information and X-ray data of the workstation 500, and adetector 840 that detects an X-ray and converts the detected X-ray intoX-ray data.

In the aforementioned example embodiment, the X-ray detector 800includes the sensor 460 that senses an X-ray. However, in this exampleembodiment, the X-ray detector 800 does not include a separate sensorand receives an activation signal from the AEC unit 900 provided in amounting unit.

First, a configuration and an operation of the AEC unit 900 will bedescribed with reference to FIGS. 20 and 21.

An X-ray imaging apparatus may perform AEC to prevent an object frombeing excessively exposed to radiation. To this end, an X-ray imagingapparatus 1 may include the AEC unit 900 that senses an X-ray dose.

As shown in FIG. 20, the AEC unit 900 includes an X-ray detector 930that senses incidence of an X-ray, a communicator 910 that sends asignal to the X-ray detector 800 and the workstation 500 when the X-rayis incident, and a controller 920 that controls the AEC unit 900.

The AEC unit 900 may be provided inside the detector mounting unit 22 a.This example will be described using the detector mounting unit 22 a ofthe imaging table 22. However, the AEC unit 900 may be provided in thedetector mounting unit 21 a of the imaging stand 21.

FIG. 21 is a front view of the detector mounting unit 22 a, according toan example embodiment. The X-ray detector 930 of the AEC unit 900 mayinclude a plurality of AEC sensors 931, 932, and 933 that independentlysense an X-ray dose. As an example, each of the AEC sensors may beimplemented as an ionization chamber. A description of the ionizationchamber is the same as described in the aforementioned exampleembodiment.

The most accurate automatic exposure control is possible when an AECsensor is located at the center of an X-ray imaging portion. To placethe center of the X-ray imaging portion at a position corresponding tothe AEC sensor or select an AEC sensor placed at the center of the X-rayimaging potion, markers Ma, Mb, and Mc indicating positions of theplurality of AEC sensors 931, 932, and 933 may be displayed on a surfaceof the detector mounting unit 22 a.

FIG. 21 shows that a total of three AEC sensors are provided, that is,two AEC sensors are provided at an upper portion and one AEC sensor isprovided at a lower portion, but this is an example. A larger or smallernumber of AEC sensors may be provided.

When an X-ray is incident on an AEC sensor, an electric current isgenerated. When the electric current is generated by the AEC sensor, thecontroller 920 may send an activation signal to the X-ray detector 800through the communicator 910. The activation signal may be a triggersignal for starting a pairing operation of the X-ray detector 800.

Also, the communicator 910 may deliver a signal corresponding to theelectric current generated by the AEC sensor to the workstation 500.

The controller 520 of the workstation 500 determines whether an X-raydose that is currently incident exceeds a critical dose on the basis ofthe delivered signal. When the X-ray dose exceeds the critical dose, thecontroller 520 may send a cutoff signal to a high-voltage generator thatsupplies high voltage to the THU 10 to stop generating the X-ray.

The communicator 910 may send signals to each of the X-ray detector 800and the workstation 500 using the same communication method or differentcommunication methods. For the latter, the communicator 910 may includedifferent communication modules.

For example, the communicator 910 may send signals to the X-ray detector800 using NFC and send signals to the workstation 500 using Wi-Fi orWFD.

There is no limitation on a method in which the communicator 910 sendssignals to the X-ray detector 800 and the workstation 500.

Referring to FIG. 19 again, the communicator 810 sends a pairing requestto the workstation 500 when an activation signal is received from theAEC unit 900. When the workstation 500 responds to the request andpairing is achieved, the X-ray detector 800 may send detectorinformation such as calibration information, remaining battery capacity,size, resolution, pixel size, and read-out rate to the workstation 500.

Also, X-ray data generated by the detector 840 may be sent to theworkstation 500. Depending on a start point of X-ray imaging, the X-raydata may be sent after being stored in the storage 830 or in real time.

Also, the communicator 810 may send signals to each of the AEC unit 900and the workstation 500 using the same communication method or differentcommunication methods. For the latter, the communicator 810 may includedifferent communication modules. In each case, the communication moduleincluded in the communicator 810 corresponds to the communicator 910 ofthe AEC unit 900 and the communicator 510 of the workstation 500.

An example of a pairing method between an X-ray detector and aworkstation according to an aspect will be described below. In thepairing method between an X-ray detector and a workstation, the X-raydetectors 200, 400, and 800, the workstations 300 and 500, the controlpanels 80 and 600, the mobile devices 100 and 700, and the AEC unit 900that have been described above may be used. Accordingly, thedescriptions with reference to FIGS. 1 to 19 may be applied to thepairing method to be described below.

FIG. 22 is a flowchart of a pairing method of an X-ray detector,according to an example embodiment.

Referring to FIG. 22, the X-ray detector 200 is tagged with the mobiledevice 100 (1010). In this case, the communicator 110 of the mobiledevice 100 may include a communication module configured to readinformation through a tagging operation, such as an NFC module or anRFID reader. The tagging operation may include authentication by a usertagging the X-ray detector 200 to be used for X-ray imaging.

The X-ray detector 200 that is tagged with the mobile device 100 sendsits own identification information to the mobile device 100 (1020). Theidentification information may include information for communication,such as an IP address or a MAC address. Also, in addition to theidentification information, the X-ray detector 200 may further senddetector information such as size, resolution, pixel size, read-outrate, and calibration information.

When the detector information is sent, the display 140 of the mobiledevice 100 may display the sent detector information, thus allowing theuser to select whether to perform pairing. The user may confirm thedetector information displayed on the display 140, determine whether theX-ray detector 200 is suitable for X-ray imaging to be performed, andselect whether to approve the pairing.

When the mobile device 100 receives the identification information fromthe X-ray detector 200 (1011), the mobile device 100 delivers thereceived identification information to the workstation 300 (1012). Also,when the detector information is also received from the X-ray detector200, the mobile device 100 may deliver the detector information inaddition to the identification information.

A communication method used when the identification information isreceived from the X-ray detector 200 and a communication method usedwhen the identification information is delivered to the workstation 300may be different or the same. As an example of the former, theidentification information may be delivered to the workstation 300through BLE. To this end, the communicator 110 of the mobile device 100may include a beacon or BLE module.

The workstation 300 receives the identification information of the X-raydetector 200 from the mobile device 100 (1030) and sends a pairingrequest to the X-ray detector 200 having the received identificationinformation (1031). Before the pairing request is sent, the user mayselect whether to perform the pairing. That is, the X-ray detector 200may select whether to send the pairing request. In this case, a screenthat checks whether to perform pairing with the X-ray detector may bedisplayed by displaying recognition identification information used bythe user to easily recognize the X-ray detector on the display 340.

The X-ray detector 200 receives the pairing request (1021) and sends apairing response (1022) to finish pairing with the workstation 300. Thatis, communication is established between the X-ray detector 200 and theworkstation 300, and the X-ray detector 200 and the workstation 300 maysend and receive signals.

The pairing between the X-ray detector 200 and the workstation 300 maynot be completed immediately, but may be completed after the pairing isfinally approved. For example, when approval of the pairing is notreceived from the user before the mobile device 100 delivers theidentification information of the X-ray detector 200 to the workstation300 or before the workstation 300 sends the pairing request to the X-raydetector 200, the workstation 300 that has received the pairing responsefrom the X-ray detector may send a pairing approval request to themobile device 100. The mobile device 100 may display a screen forreceiving approval of the pairing from the user. When the user inputs apairing approval command, the mobile device 100 may send a pairingapproval signal to the workstation 300. When the workstation 300receives the pairing approval signal, the pairing between the X-raydetector 200 and the workstation 300 may be completed.

When the mobile device 100 does not deliver the detector information tothe workstation 300, the X-ray detector 200 paired with the workstation300 may send the detector information (1023), and the workstation 300may receive the detection information (1032).

When X-ray imaging is performed and an X-ray is emitted from the THU 10,the X-ray detector 200 detects the X-ray (1024) and generates X-raydata, and sends the generated X-ray data to the workstation 300 pairedwith the X-ray detector 200 (1025).

The workstation 300 receives the X-ray data (1033) and processes thereceived X-ray data on the basis of the detector information of theX-ray detector 200 to generate an effective X-ray image (1034).

In the aforementioned example, the pairing between the X-ray detector200 and the workstation 300 has been described. However, the X-raydetector 200 may be paired with the control panel 80 of the THU 10. Inthis case, the pairing method between the X-ray detector 200 and theworkstation 300 may also be applied to the X-ray detector 200 and thecontrol panel 80.

The pairing method of an X-ray detector according to an exampleembodiment may include some or all of the steps that have been describedwith reference to FIG. 19. For example, the pairing method may includesteps 1010, 1011, and 1012 that are performed using the mobile device100, steps 1020, 1021, 1022, 1023, and 1024 that are performed using theX-ray detector 200, or steps 1030, 1031, 1032, and 1033 that areperformed using the workstation 300.

FIG. 23 is a flowchart of a pairing method of an X-ray detector,according to another example embodiment.

Referring to FIG. 23, when the X-ray detector 400 senses an X-ray(1110), a communication module for communicating with the workstation500 is activated to send a pairing request to the workstation 500(1111). In this case, the sensor 460 provided in the X-ray detector 400may sense incidence of the X-ray.

The workstation 500 receives the pairing request (1120) and sends apairing response to the X-ray detector 400.

Likewise, pairing between the X-ray detector 400 and the workstation 500may not be completed immediately, but may be completed after the pairingis finally approved. For example, before or after the workstation 500sends the pairing response (1121) to the X-ray detector 400, theworkstation 500 that has received the pairing request from the X-raydetector may send a pairing approval request to the mobile device 700.The mobile device 700 may display a screen for receiving approval of thepairing from the user. When the user inputs a pairing approval command,the mobile device 100 may send a pairing approval signal to theworkstation 500. When the workstation 500 receives the pairing approvalsignal, the pairing between the X-ray detector 400 and the workstation500 may be completed. When the workstation 500 has not sent the pairingresponse to the X-ray detector 400 upon reception of the pairingapproval signal, the workstation 500 may send the pairing response tothe X-ray detector 400 and finish the pairing.

When the pairing between the X-ray detector 400 and the workstation 500is completed, the X-ray detector 400 may send detector information tothe workstation 500 (1112), and the workstation 500 may receive thedetector information (1122).

The X-ray sensed in step 1110 may be emitted as a pre-shot for pairingactivation or by a main shot for X-ray imaging. For the former, the mainshot is made after the pairing is completed, and the X-ray detector 400may detect the X-ray (1113) and generate X-ray data, and transmit thegenerated X-ray data to the workstation 500 (1114). For the latter, thesensing of the X-ray and the detection of the X-ray (1113) may besimultaneously achieved, and the generated X-ray data may be stored inthe storage 430 and then sent to the workstation 500 when the X-raydetector 400 and the workstation 500 are paired.

The workstation 500 receives the X-ray data (1123) and processes thereceived X-ray data on the basis of the detector information to generatean effective X-ray image (1124).

According to still another example embodiment, the X-ray detector 800may receive an activation signal from the AEC unit 900 provided forcontrolling an X-ray dose to send a pairing request to the workstation500 instead of including a separate sensor. Subsequent operations arethe same as those in the aforementioned example embodiment.

Some of the operations of the mobile devices 100 and 700, the operationsof the workstations 300 and 500, the operations of the control panels 80and 600, and the pairing method of an X-ray detector that have beendescribed may be stored as a program in a computer-readable recordingmedium. That is, the computer-readable recording medium may store aprogram including an instruction for executing some of theaforementioned operations.

The recording medium may be a magnetic recording medium such as a floppydisk and a hard disk or an optical recording medium such as a CD-ROM anda DVD. However, the type of the recording medium is not limited to theabove-described example.

The recording medium may be included in a server that provides anapplication or program. The mobile devices 100 and 700, the controlpanels 80 and 600, or the workstations 300 or 500 may access the serverthrough a communication protocol such as the Internet and download theprogram.

According to the aforementioned example embodiments, it is possible tofacilitate pairing of the X-ray detector and the workstation without aprocess in which a user directly inputs information on the X-raydetector.

It is also possible to enable more accurate pairing of an X-ray detectorand a workstation by preventing an error that may occur while a userinputs information on the X-ray detector.

It is also possible to reduce a work load of a user by using a lightweight mobile device or emitting only an X-ray to automatically performpairing without needing to directly move an X-ray detector to pair theX-ray detector with a workstation.

According to the X-ray detector, the mobile device, the host device, theX-ray imaging apparatus, and the method of pairing an X-ray detectorwith a host device according to an aspect, it is possible to simply andaccurately pair an X-ray detector with a host device without a task of auser directly entering information regarding the X-ray detector into ahost device or the like.

In addition, the example embodiments may also be implemented throughcomputer-readable code and/or instructions on a medium, e.g., acomputer-readable medium, to control at least one processing element toimplement any above-described embodiments. The medium may correspond toany medium or media that may serve as a storage and/or performtransmission of the computer-readable code.

The computer-readable code may be recorded and/or transferred on amedium in a variety of ways, and examples of the medium includerecording media, such as magnetic storage media (e.g., ROM, floppydisks, hard disks, etc.) and optical recording media (e.g., compact discread only memories (CD-ROMs) or digital versatile discs (DVDs)), andtransmission media such as Internet transmission media. Thus, the mediummay have a structure suitable for storing or carrying a signal orinformation, such as a device carrying a bitstream according to one ormore example embodiments. The medium may also be on a distributednetwork, so that the computer-readable code is stored and/or transferredon the medium and executed in a distributed fashion. Furthermore, theprocessing element may include a processor or a computer processor, andthe processing element may be distributed and/or included in a singledevice.

The above-described subject matter of the example embodiments is to beconsidered illustrative and not restrictive, and numerous othermodifications and example embodiments can be devised by those skilled inthe art that will fall within the spirit and scope of the principles ofthe example embodiments. Accordingly, the example embodiments anddrawings of the example embodiments are to be considered descriptive andnot restrictive of the example embodiments, and do not limit the scopeof the example embodiments. The scope of the example embodiments may bedetermined by the following claims and their appropriate legalequivalents.

What is claimed is:
 1. An X-ray detector comprising: a detectorconfigured to convert an X-ray incident on the detector into X-ray data;and at least one processor configured to control the X-ray detector to,in response to the X-ray being incident on the detector, send a pairingrequest to a host device to request pairing of the X-ray detector withthe host device, and in response to receiving a pairing response to thepairing request from the host device, perform control to complete thepairing of the X-ray detector with the host device.
 2. The X-raydetector according to claim 1, wherein the detector is activatable, andconverts the incident X-ray into the X-ray data after being activated,and the detector is configured to be activated in response to the X-raybeing incident on the detector.
 3. The X-ray detector according to claim1, further comprising: a storage storing the X-ray data, wherein the atleast one procesor is configured to, when the detector converts theX-ray into the X-ray data prior to the completion of the pairing of theX-ray detector with the host device, perform control to transmit theX-ray data stored in the storage to the host device after completion ofthe pairing of the X-ray detector with the host device.
 4. The X-raydetector according to claim 1, further comprising: at least onecommunicator including any one or any combination of a Wi-Fi module anda Wi-Fi Direct module that are operable to send the pairing request andto receive the pairing response.
 5. An X-ray detector comprising: adetector configured to convert an X-ray incident on the detector intoX-ray data; a sensor configured to sense incidence of the X-ray on thedetector; and at least one processor configured to control the X-raydetector to, in response to the sensor sensing incidence of the X-ray onthe detector, send a pairing request to a host device to request pairingof the X-ray detector with the host device, and in response to receivinga pairing response to the pairing request from the host device, performcontrol to complete the pairing of the X-ray detector with the hostdevice.
 6. The X-ray detector according to claim 5, wherein the detectoris activatable, and converts the X-ray incident on the detector into theX-ray data after being activated, and the at least one processor isconfigured to activate the detector in response to the sensor sensingincidence of the X-ray on the detector.
 7. The X-ray detector accordingto claim 5, further comprising: a storage storing the X-ray data,wherein the at least one procesor is configured to, when the detectorconverts the X-ray into the X-ray data prior to the completion of thepairing of the X-ray detector with the host device, perform control totransmit the X-ray data stored in the storage to the host device aftercompletion of the pairing of the X-ray detector with the host device. 8.The X-ray detector according to claim 5, further comprising: at leastone communicator including any one or any combination of a Wi-Fi moduleand a Wi-Fi Direct module that are operable to send the pairing requestand to receive the pairing response.
 9. An X-ray detector comprising: adetector which is activatable, and which is configured to, whenactivated, convert an X-ray incident on the detector into X-ray data; asensor configured to sense incidence of the X-ray on the detector; andat least one processor configured to control the X-ray detector to, inresponse to the sensor sensing incidence of the X-ray on the detector,activate the detector so that the detector converts the X-ray into theX-ray data, send a pairing request to a host device to request pairingof the X-ray detector with the host device, and in response to receivinga pairing response to the pairing request from the host device, performcontrol to complete the pairing of the X-ray detector with the hostdevice.
 10. The X-ray detector according to claim 9, further comprising:a storage storing the X-ray data, wherein the at least one procesor isconfigured to, when the detector converts the X-ray into the X-ray dataprior to the completion of the pairing of the X-ray detector with thehost device, perform control to transmit the X-ray data stored in thestorage to the host device after completion of the pairing of the X-raydetector with the host device.
 11. The X-ray detector according to claim9, further comprising: at least one communicator including any one orany combination of a Wi-Fi module and a Wi-Fi Direct module that areoperable to send the pairing request and to receive the pairingresponse.